[0001] The invention relates to a method of detecting the presence or absence of an article
on or from a vacuum pick-up means which can be placed in communication with a vacuum
source and which is operable to pick-up, transport and place an article, the article
being picked up and held by the pick-up means under the influence of the vacuum and
being released when the vacuum is interrupted or destroyed, and the difference in
the pressures obtaining in the pick-up means when the latter is in communication with
the vacuum source and an article is present on the pick-up means and when the latter
is in communication with the vacuum source and there is no article present on the
pick-up means, being utilised in the production of a test or failure signal.
[0002] For the picking-up, transport, transfer and placement of articles by means of vacuum
pick-up means it is desirable, if not necessary, to know:
a. that the article has indeed been drawn to and picked up by the pick-up means;
b. that the article remains attached to the pick-up means over the entire transport
path until the instant at which the article is placed;
c. that the article has in fact been placed and left at the appropriate location.
[0003] Detection of the presence or absence of an article on or from the pick-up means can
be performed in various ways, for example, directly or indirectly by means of sensors,
by detection, for instance by mechanical or optical means, of a relative displacement
of the pick-up means, or by detection by means of a pressure detector or a flowmeter.
[0004] A method of the kind set forth (and defined in the precharacterising part of claim
1) is known from United States Patent Specification 3,453,714; this specification
concerns an indirect detection method which utilizes a diaphragm which reacts to a
difference in vacuum. A further indirect method which utilizes a differential pressure
switch is known from United States Patent Specification 4,116,348. Detection on an
optical basis by means of a photocell (again an indirect method) is known from United
States Patent Specification 3,731,867. Finally, European Patent Application 0.036.826
discloses a detection method which utilizes a pressure detector as well as an optical
detection method. The known detection methods either use a displaceable member and/or
react to a differential pressure.
[0005] The present invention has for its object to improve upon the known detection methods,
to accelerate the detection process itself, and to enhance the reliability of the
detection.
[0006] This object is achieved in accordance with the invention in that the air flow which
is produced by the vacuum when the pick-up means is in communication with the vacuum
source and there is no article present on the pick-up means, is utilized to generate
the test or failure signal, said air flow being converted into an acoustic signal
which indicates the absence of an article from the pick-up means.
[0007] Using the method in accordance with the invention, referred to hereinafter as the
same detection method, fast detection is achieved in a simple manner, the intensity
of the acoustic signal generated a whistling or a noise signal, being a measure of
the amplitude of the signal and also a measure of the rate of the air flow. When the
vacuum is switched on, a maximum air flow and hence a maximum acoustic signal is to
be expected when the free end of the pick-up means is not closed by an article, i.e.
when no article is present on the pick-up means; the air flow and hence the acoustic
signal are minimum when the pick-up means is closed by an article present thereon.
[0008] The article to be picked up and transported may be of various dimensions. For articles
having comparatively large dimensions, for example, of the order of magnitude of decimeters,
several pick-up means are used; for smaller articles having dimensions of the order
of magnitude of millimeters, a single pick-up means will suffice.
[0009] The acoustic signal can be generated by means of a whistle or noise generator arranged
in the air flow. However, according to a preferred method in accordance with the invention
the acoustic signal is produced by turbulence created in the air flow.
[0010] The acoustic signal is preferably amplified.
[0011] In a further preferred method in accordance with the invention, the acoustic signal
is converted into an electric, electronic and/or optical signal.
[0012] The invention can be used particularly advantageously for the picking-up, transport
and placement as well as for the treatment and handling of electronic and/or electrical
components in general.
[0013] The increasing degree of miniaturization in the electronics industry has given rise
to the development of plate-shaped, block-shaped or cylindrical components without
connection wires which components are also referred to as "chip-type" components.
These components have comparatively small dimensions of the order of magnitude of
millimeters; for example, a frequently used component has the standard dimensions
3.2 x 1.6 x 0.8 millimeters. For the placement of such chip-type components on a substrate,
the components are presented in a given position, packed in a given package or not
as the case may be, and are picked up by a transfer member to be deposited on the
track side of the substrate in the appropriate location; the components are retained
in position by means of a fixing agent, such as solder paste or glue, applied to the
substrate and/or the components in advance; subsequently, the components are soldered
in position by means of a suitable process. Components comprising short connection
members, such as diodes or transistors, are transferred to and placed on the substrate
in the same manner. Considering the small dimensions of said components, the dense
track pattern on the substrate and the required accurate positioning of the components
on the substrate, such components can no longer be transported, transferred and placed
by means of purely mechanical gripping means such as those customarily used for the
handling of conventional components having connection wires. For the handling of chip-type
components, generally a vacuum pick-up means is used which is connected to a vacuum
source and by means of which a component is picked up in a pick-up position, from
a given package or not, after which the pick-up means with the component attached
thereto is moved to the mounting position over a substrate and ultimately the component
is placed on the substrate by the pick-up means and is retained thereon by a fixing
agent, for example, glue or solder paste, applied to the substrate and/ or the component
in advance. After removal of the vacuum the pick-up means is moved to the pick-up
position again, after which a further component can be picked up and a new cycle may
commence.
[0014] The invention can be used particularly advantageously for placing electrical and/or
electronic components on a substrate, each component being transferred from a pick-up
position to a placement position on the substrate by means of a vacuum pick-up means;
the picking-up of each component in the pick-up position and the placement of the
component on the substrate are checked by means of the sonic detection method according
to the invention.
[0015] When a comparatively large number of components are to be placed, for example, some
tens of components, on the same substrate, it is absolutely necessary to be certain
that the components have been picked up, transported and placed. If a single component
is not picked up or not actually left on the substrate, the mounting process is liable
to be disturbed and an unacceptable rejection percentage may occur; also, unacceptable
uncertainty arises as regards the reliable execution of the mounting process. These
problems and uncertainties are avoided by using the sonic detection method in accordance
with the invention.
[0016] In this context the term "substrate" is also to be understood to mean, for example,
a tape-like package strip with cavities, chambers or cut-outs in which the components
are accommodated. By using the method in accordance with the invention for the packaging
of components, it is ensured that each cavity, chamber or cut-out is actually provided
with a component.
[0017] If desired or if necessary, of course, the presence of the component can also be
checked just before it is placed on the substrate. It can thus be detected whether
the component has fallen off the pick-up means during the transport from the pick-up
position to the placement position.
[0018] The sonic detection method in accordance with the invention can also be used to advantage
in a mounting process in which each component is temporarily halted in an intermediate
position during the transport from the pick-up position to the placement position,
a fixing agent being applied to the component in said intermediate position. The presence
of the component in the intermediate position can also be checked by means of the
sonic detection method in accordance with the invention.
[0019] A substrate provided with components by means of the described mounting method is
free from placement errors; such errors are to be understood to mean notably positions
which are not provided with the component in the desired manner.
[0020] The invention also relates to a device for performing the method according to the
invention, comprising at least one displaceable vacuum pick-up means which is connected
to a vacuum source, and a valve which is operable to establish and interrupt communication
between the vacuum pick-up means and the vacuum source. The device in accordance with
the invention is characterized in that a sound generator is interposed in the connection
between the vacuum pick-up means and the vacuum source. This device will be referred
to hereinafter as sonic detector. In one embodiment, the sound generator is constructed
simply to produce a whistle. However, the sound generator in a preferred embodiment
is constructed as a vortex chamber. The vortex chamber causes turbulence in the air
flow produced by the vacuum, said turbulence being accompanied by sound and noise.
It is not necessary to create a differential pressure by means of constrictions in
this embodiment. Because such a simple sound or noise generator does not comprise
moving parts and offers ample passages for the air flow without constrictions, the
risk of breakdown due to contamination is very small.
[0021] By arranging a microphone in the vortex chamber in a preferred embodiment of the
device in accordance with the invention, the sound produced by the turbulent air flow
can be simply converted into electronic signals.
[0022] In a preferred embodiment of the device in accordance with the invention, the microphone
is connected to an electronic signal-processing unit. This unit comprises, for example,
a high-pass filter, an amplifier and a threshold-value adjustment device for processing
and converting the signals received via the microphone into "yes" and "no" signals
which are applied to an electronic control device which can influence the mechanical
device. Disturbing extraneous sound signals which are not generated by the turbulent
air flow are not amplified and transmitted. Examples of such sound signals are speech
and music sounds in a frequency range of up to approximately 10,000 Hz. These sound
signals are filtered out by the high-pass filter. Adjustment of a threshold value
by means of the threshold-value adjustment device enables adjustment of a minimum
value of the signal to which the sonic detector must still react. If a component is
present on the vacuum pick-up means the sound has a minimum value; if there is no
component present the sound has a maximum value. Between a component and the vacuum
pick-up means itself, however, always some leakage occurs, because the surface of
the component is not absolutely smooth. This fact can be taken into account by adjustment
of the threshold value.
[0023] Full benefit is derived from the advantages of the described sonic detector in combination
with an apparatus proposed in EP-A-71303 in the name of Applicant. This is an apparatus
for placing a plurality of electrical and/or electronic components on a substrate
and comprises a frame, a drive mechanism, a carrier for a substrate and a transfer
mechanism with a plurality of vacuum pick-up means; in such an apparatus the plurality
of vacuum pick-up means can be placed in communication with a common vacuum source
via a single, common valve. Thanks to its simplicity and resultant reliability, the
sonic detector is extremely suitable for multiple use, so that the reliability of
the overall device is also improved whilst the costs of the sonic detector are low.
[0024] The above mentioned apparatus may comprise a mechanism for the application of a fixing
agent to the components, said mechanism comprising a plurality of applicators which
are displaceable between a rest position in which the applicators can receive a quantity
of fixing agent and an operative position in which they can be brought into contact
with the lower sides of the components. Thanks to the sonic detectors, any vacuum
pick-up means which does not carry a component for some reason can be prevented from
contacting one of the applicators, so that the vacuum duct of the relevant vacuum
pick-up means cannot become clogged by the fixing agent.
[0025] An example of the method and embodiments of the detection device and the mounting
apparatus according to the invention will be described in detail hereinafter with
reference to the accompanying drawing, in which:
Figure 1 shows diagrammatically an embodiment of the detection device in accordance
with the invention for detecting the presence of an article on or its absence from
a vacuum pick-up means;
Figure 1A shows a part of the pick-up means shown in Figure 1;
Figure 2 shows diagrammatically an embodiment of an apparatus for mounting electrical
and/ or electronic components on a substrate;
Figure 3 is a diagrammatic longitudinal sectional side view, taken along the line
III-III in Figure 4, of a transfer device which forms of part of the apparatus shown
in Figure 2, the transfer device being shown in the pick-up position;
Figure 4 is a transverse sectional view of the transfer device taken along the line
IV-IV in Figure 3;
Figure 5 is a sectional side view, taken along the line V-V in Figure 6, of the transfer
device in the mounting position;
Figure 6 is a sectional plan view, taken along the line VI-VI in Figure 5, of the
transfer device.
[0026] Figure 1 shows diagrammatically a detection device 101 for detecting the presence
of an article 103 on, or its absence from a vacuum pick-up means 105 which comprises
a suction tube 106.
[0027] The pick-up means 105 is connected to a vacuum source 109 via a flexible tube 107.
By means of a valve 111, the pick-up means 105 can be placed in communication with
the vacuum source 109 or with the ambient atmosphere or a compressed-air source 113.
The detection device 101 operates on a sonid basis. To this end, it comprises a noise
or sound generator 115, which consists of a vortex chamber 119 with an inlet 121 and
an outlet 123 which extend at right angles to one another and which have no constriction.
In the vortex chamber 119 there is arranged a microphone 125, preferably an electret
microphone, which is connected to an electronic signal-processing unit 127. This unit
comprises, for example, a high-pass filter, an amplifier, a rectifier, a smoothing
capacitor and a threshold-value adjustment device. The "yes" and "no" signals from
the latter device are applied to a control device in the form of optical, acoustic
and/ or electric signals. The sound generator 115 is mounted on a fixed base 133 by
means of resilient or absorbing elements 131.
[0028] The operation of the sonic detection device is as follows: For the picking-up, transporting
and placement of an article 103, the vacuum pick-up means 105 is connected, via the
valve 111, to the vacuum source 109, so that ambient air is drawn into the pick-up
means through the free end thereof which is not closed, and an air flow is produced
in the suction tube 106 and the tube 107. When the free end of the pick-up means 105
is brought close to or into contact with the article 103 to be picked up, the article
is drawn onto the free end of the pick-up means by the air flow and is held thereon
by the resulting pressure differential across the article, as shown in Figure 1A.
The article 103 can then be transported to the desired location by moving the pick-up
means 105. To place the article in the desired location, the vacuum in the suction
tube 106 is destroyed by cutting-off the pick-up means 105 from the vacuum source
109 and placing it in communication with atmosphere by means of the valve 111. If
desired or if necessary, the pick-up means 105 may be connected to a compressed-air
source 113, so that the article 103 is detached from the pick-up means 105 in a positive,
i.e. forceful manner. This effect may be important in handling very light articles.
The situation in which the pick-up means 105 is connected to the vacuum source 109
without the suction tube 106, for whatever reason, being closed by the article 103,
is detected and signalled by the sound or noise generator 115. In this situation air
flow in the suction tube 106 and the tube 107 swirls in the vortex chamber 119 due
to the acute, abrupt directional change in the air flow between the inlet 121 and
the outlet 123. This air turbulence produces sound or noise signals, which signals
are received by the microphone 125 and are subsequently amplified by the electronic
signal-processing unit 127, after which they are further processed for conversion
into electric, acoustic, optical etc. signals. The filter of the unit 127 prevents
the transmission of extraneous sounds in an audible frequency range of up to approximately
10,000 Hz; such sounds are filtered out by the filter. Obviously, acoustic signals
received by the microphone 125 can be processed to form a positive or a negative indication,
i.e. the absence or presence, respectively, of an article on or from the end of the
pick-up means is signalled in an optical, acoustic or other perceptible manner.
[0029] The embodiment shown in Figure 1 concerns a sonic detection device comprising a single
pick-up means which is suitable for picking-up a single article. For picking-up, transporting
and placing larger articles, a plurality of vacuum pick-up means can be used, each
of which comprises a sonic detection device in accordance with the invention and which
may or may not be operated together.
[0030] The vacuum pick-up means 105 is constructed as a simple suction tube in the embodiment
shown. Other embodiments can be used with the same advantages and with the same effect,
for example, a vacuum pick-up means of the type comprising a suction tube which is
slidable in a tube.
[0031] In view of its reliability and low susceptibility to breakdown and contamination
and its small dimensions, the sonic detection device in accordance with the invention
can be used particularly advantageously in an apparatus for placing and mounting electrical
and/or electronic components on a substrate, as shown in the Figures 2 to 6.
[0032] The reference numeral 1 in Figure 2 denotes a substrate, for example, a printed-circuit
board which is already provided on its lower side with conventional components 3,
the lead-outs of which are inserted in holes in the substrate. A large number of further
components 103 which are very small and which do not comprise lead-outs are to be
placed on the upper side of the substrate. The dimensions of this type of component,
also referred to as a "chip" are of the order of magnitude of millimeters and the
components must be very accurately positioned on the substrate at a very small distance
from one another. Common dimensions of a component are 3.2 x 1.6 x 0.8 mm. The substrate
1 is supported by a substrate carrier 7 which comprises positioning elements 8. The
components 103 to be placed are packaged in tapes 9 which comprise feed-sprocket perforations,
the components being loosely arranged in openings in the tapes which are closed at
the lower side by a lower foil and at the upper side by a cover foil.
[0033] A number of these tapes is wound on rotatable reels 11 in a holder 13. The number
of reels present in the holder 13 depends on the requirements. It is common to have
thirty-two reels arranged at two levels in the holder 13. The tapes 9 extend from
the reels 11 to a device 15 (not described) for feeding the tapes to a given pick-up
position P. Such a device 15 forms the subject of a previously filed application.
In the present embodiment this device is constructed to feed thirty-two components
103 during each cycle. The components 103 are removed from the tapes 9 and transferred
to the substrate 1 by a transfer device 21. The device 15 is constructed so that the
tapes 9 can be fed to the pick-up position P together or individually. The transfer
device 21 consists mainly of a frame 23, a transfer mechanism 25, a drive mechanism
27 and said substrate carrier 7. These parts are mounted on a base 28.
[0034] The transfer mechanism 25, which will now be described with reference to Figures
3 to 6, comprises a plurality of transfer arms 29 which are equal in number to the
components to be simultaneously transferred, namely, thirty-two in the present embodiment.
Each transfer arm 29 comprises a vacuum pick-up means 105. The transfer arms 29 are
slidable independently of one another in a single, common carriage 31 which is itself
movable in reciprocal directions in the frame 23. The carriage is driven by the drive
mechanism 27 which is shown in Figure 2 and which comprises a motor (not shown), a
cam disc 33 and a lever 35 with a cam-follower in the form of a roller 37. the frame
23 consists mainly of two sidewalls 41 as shown in Figure 4. The carriage 31 has a
tubular form with a rectangular cross-section. In its movement the carriage is guided
by rollers 43 which are mounted on the sides of the carriage and which run along two
rails 45 which are mounted on the inner sides of the sidewalls 41 and which freely
project from the frame 23 beyond the carrier 7. The carriage 31 can thus move freely
between the sidewalls 41. In the inner sides of the upper and lower walls of the carriage
there are provided parallel grooves 47, thirty-two grooves in each wall in the present
embodiment. These grooves 47, in co-operation with ball bearings 49 and sliding blocks
51, to serve to guide in a sliding manner a corresponding number of transfer arms
29. The ball bearings 49, one on the upper side and one on the lower side of each
transfer arm, ensure that the transfer arms are supported without play at their rear
ends. This support ensures that the vertical position of the transfer arms is maintained.
The sliding blocks 51 are so proportioned that some play exists between the transfer
arms 29 and the carriage 31 in the transverse direction with respect to the carriage
31, the transfer arms pivoting in this play about vertical axes defined by the ball
bearings 49. At its end which is remote from the frame 23 each transfer arm 29 comprises
a vacuum pick-up means 105 which is of the type comprising a suction tube in the embodiment
shown. The suction tube 53 is displaceable in the vertical direction (Figure 3) by
means of a piston 55. Each transfer arm 29 comprises a compressed-air duct 57 which
can be connected, via an associated flexible tube 59 and an associated electromagnetic
valve 60, to a source of compressed air, and which communicates with the space above
the piston 55 in the respective pick-up means 105. The electromagnetic valves 60 can
be actuated separately so that the suction tubes 53 can be displaced individually.
Also in each transfer arm 29 there is provided a vacuum duct 61 which communicates
with the respective suction tube 53 and which is connected via a flexible tube 107
to a vacuum source 109 in the manner already described with reference to Figure 1,
each vacuum duct 61 being connected to the vacuum source via a sonic detection device
101 and a common pneumatic chamber 135 to which the vacuum source 109 and possibly
also a compressed air source 113 are connected. The reference numeral 111 designates
a valve similar to that already mentioned with reference to Figure 1. The suction
tubes 53 are each retained in the neutral rest position shown in Figure 3 by a spring
65, the respective transfer arms 29 then being in their pick-up positions and ready
to pick-up the components 103 which are in the pick-up position P. In this position,
a projection 67 on the upper end of each pick-up means 105 bears against an abutment
bar 69 comprising recesses 70 and serving as a multiple fixed abutment. The reference
numeral 71 designates a program plate which is replaceably mounted on the frame 23
and which comprises stops 73 which are engageable by the projections 67 on the pick-up
means 105 to arrest the transfer arms 29 in the mounting positions shown in Figure
5. As is shown in Figure 4, the program plate 71 is accurately positioned with respect
to the frame 23 by means of locating holes 75 which co-operate with locating pins
77. The program plate 71 rests on two elongate supports 78 mounted on the sidewalls
41 of the frame 23.
[0035] The reference numeral 81 designates a mechanism for applying a fixing agent or adhesive,
such as solder paste or glue, to the lower sides of the components. The mechanism
81 comprises mainly an elongate arm 83 on which is mounted a row of applicators 85,
the number of applicators being equal to the number of components to be placed. The
arm 83 with the applicators 85 is displaceable in the vertical direction from the
rest position shown in Figure 2, in which the applicators 85 are immersed in a container
87 containing fixing agent, to an operative position (not shown) in which the free
ends of the applicators 85 can contact the lower sides of the components to be placed.
[0036] The cycle of operations of the above apparatus will now be described. First, all
thirty-two transfer arms 29 with the thirty-two pick-up means 105 have to be brought
to their pick-up positions. To this end, the carriage 31 is moved towards the abutment
bar 69 by the drive mechanism 27. The sliding blocks 51 slide in the grooves 47 of
the carriage 31 with an accurately defined friction. The friction is such that when
the carriage 31 is driven the transfer arms 29 move with it. However, as soon as the
projection 67 of the pick-up means of a transfer arm 29 contacts the abutment bar
69, the relevant arm with its pick-up means is stopped and the arm remains stationary
while the carriage 31 continues its movement, the sliding blocks 51 and the ball bearings
41 of the arm remaining stationary in the respective grooves 47 in the carriage 31.
[0037] During the displacement of the carriage 31 to the pick-up position, the transfer
arms 29 move forward until the projections 67 of all the pick-up means 105 contact
the fixed abutment bar 69. The transfer arms are then all stationary in the pick-up
positions. The projections 67 and the recesses 70 in the abutment bar 69 are so shaped,
proportioned and adjusted that in the pick-up positions of the transfer arms, the
centre lines of the suction tubes 53 are situated exactly in one line over the pick-up
positions P of the components which are presented in one line.
[0038] Subsequently, the suction tubes 53 are displaced downwards by compressed air against
the force of the springs 65, the compressed air being supplied via the tubes 59 and
the compressed-air ducts 57 in the transfer arms 29 by operation of the valves 60.
The components 103 present in the pick-up position P are then picked up and held by
the respective suction tubes 53 which are connected, via the respective vacuum ducts
61 and tubes 107, to the pneumatic chamber 135 which is connected to the vacuum source
109 via the valve 111.
[0039] Upon interruption of the supply of compressed air to the pick-up means the suction
tubes 53 are raised again by the springs 65, and the carriage 31 is then moved backwards
by the drive mechanism 47, the transfer arms 29 being taken along with the carriage
and bringing the pick-up means 105 to the entry side of the program plate 71. All
the pick-up means 105 will then have travelled a first distance A along straight lines
parallel to one another, the distance A being the same for all the pick-up means.
As has already been described in detail in said previous application in the name of
the present Applicants, at the entry side of the program plate 71 there are provided
catchor elements (not shown) which lead to the front ends of flexible guide elements.
The other end portion of each guide element is secured in an abutment block on the
program plate 71 so that a pick-up means 105 is arrested by the relevant stop 73 in
a mounting position exactly over the placement position of the component 103, i.e.
the position in which the component is to be placed on the substrate 1. The projections
67 on the pick-up means 105 are guided by the guide elements as far as the stops 73,
where the transfer arms 29 are arrested by engagement of the projections 67 with the
stops 73. The pick-up means will then have travelled a second distance B, with or
without lateral displacement. The distance B may be the same for all the pick-up means
or it may differ from one pick-up means to another.
[0040] When all the pick-up means 105 have contacted the relevant stops 73, the suction
tubes 53 are moved downwards again by means of compressed air and the components 103
are placed on the substrate 1 by destroying the vacuum in the suction tubes or by
connecting the suction tubes to the compressed-air source 113. Subsequently, the supply
of compressed air to the spaces above the pistons 55 in the pick-up means 105 is interrupted
again and the suction tubes 53 are raised by the springs 65. Finally, the carriage
31 is moved forwards again until all the pick-up means 105 contact the fixed abutment
bar 69 again. In the meantime, all the tapes 9 have been advanced one position so
that a further component is presented at each pick-up position P.
[0041] The detection of the presence of a component on, or its absence from, a pick-up means
105 and of the correct picking-up, the trouble-free transport and the correct placement
of the components during the above-described cycle of operations, is effected as follows:
The suction tubes 53 of the pick-up means 105 are in communication with the vacuum
source 103 during the picking-up of the components 103 and during the transport of
the components until they are left deposited in their placement positions. A first
"presence" detection is performed at the picking-up of the components. Should one
of the suction tubes 53 fall to pick up a component, for example, because no component
is present in the relevant pick-up position P, this is detected and signalled by the
associated sonic detection device 101 already described with reference to Figure 1.
By means of the control device which forms part of the signal-processing unit 127,
the drive for all tapes 9 is blocked, except for the tape 9 which is associated with
the empty position and which is individually advanced one position to position a component
103 in the previously empty pick-up position P. The pick-up means 105 whose suction
tube 53 is still without a component is pneumatically actuated through the associated
the associated valve 60 so that this suction tube performs a downward stroke and picks
up the component, whilst the other suction tubes remain in their upper positions.
After picking up the component the suction tube is raised by the spring 65 and the
cycle is continued by all the pick-up means together. Should several pick-up attempts
fail, the apparatus is stopped for further checking.
[0042] By performing a further presence detection at the instant at which the pick-up means
are located over the respective placement positions on the substrate, the loss of
a component from one of the pick-up means during the transport of the component from
the pick-up position to the placement position can be detected. The absence of a component
is detected and signalled again by the associated sonic detection device 101 which,
via the signal-processing unit 127 prevents actuation of the relevant electromagnetic
valve 60. The empty suction tube 53 remains in the upper position, whilst the remaining
suction tubes are lowered to place their components on the substrate. Subsequently,
all the pick-up means are returned to the pick-up position in which the next components
in the position P are picked up. The transfer device then performs another mounting
cycle during which, however, a component is placed on the substrate only in the placement
position which is still empty, the other suction tubes remaining cut off from the
compressed-air supply and not being lowered. Subsequently, all the pick-up means return
to the pick-up position, where only the suction tube which is then empty picks up
a component, after which the normal mounting cycle is resumed.
[0043] The sonic detection method can also be used to check whether the components have
in fact been left in their placement positions on the substrate. If they have, a signal
is supplied by all the detection devices; if no signal is supplied for a particular
pick-up means, either the respective component has not been left on the substrate
by that pick-up means or the latter's suction tube has become clogged.
[0044] In all cases where a particular component is not placed on the substrate in the desired
manner for some reason, only one component is mounted, in the above-described manner,
during the next mounting cycle.
[0045] For fixing the components to the substrate, an adhesive can be applied to the substrate,
to the components or to both. The above test makes it possible to check whether adhesive
is indeed present on the substrate and/or the component. If it is, the components
will normally be retained on the substrate due to the viscosity of the adhesive, in
spite of the vacuum in the pick-up means. The indication by the respective sonic detector
of the presence of a component on one of the pick-up means at the completion of a
mounting cycle thus means that no adhesive was present on the relevant component and/or
the substrate.
[0046] In order to ensure that all the components are left on the substrate, the pneumatic
chamber 135 can be switched over, by means of the two-way valve 111, to the compressed-air
source 113 at the instant at which the components are placed on the substrate, so
that the vacuum in the pick-up means 105 is destroyed and the suction tubes 53 are
also purged. The components are thus ejected as it were, from the suction tubes; at
the same time the suction tubes 53 are purged.
[0047] In the situations described, suction tubes which do not carry a component are isolated
from the supply of compressed air by the respective electromagnetic valves 60. The
pistons 55 which displace these suction tubes 53 are consequently retained in their
upper, rest positions by the associated springs 65 and are thus prevented from contacting
adhesive on the substrate, so that contamination and clogging of the suction tubes
by adhesive are prevented. In the same way an empty suction tube is prevented from
coming into contact with adhesive on an applicator 85 in the station 81.
[0048] In the embodiment described and shown, the suction tubes 53 are moved to their rest
positions and retained there by the springs 65. Obviously, pneumatic means can alternatively
be used for this purpose.
1. A method of detecting the presence or absence of an article on or from a vacuum
pick-up means (105) which can be placed in communication with a vacuum source (109)
and which is operable to pick up, transport and place an article, the article being
picked up and held by the pick-up means under influence of the vacuum and being released
when the vacuum is interrupted or destroyed, and the difference in the pressure obtaining
in the pick-up means when the latter is in communication with the vacuum source and
an article is present on the pick-up means and when the latter is in communication
with the vacuum source and there is no article present on the pick-up means, being
utilized in the production of a test or failure signal, characterized in that the
air flow which is produced by the vacuum when the pick-up means is in communication
with the vacuum source and there is no article present on the pick-up means is utilized
to generate the test or failure signal, said airflow being converted into an acoustic
signal which indicates the absence of an article from the pick-up means.
2. A method as claimed in Claim 1, characterized in that the acoustic signal is produced
by turbulence created in the air flow.
3. A method as claimed in Claim 1 or 2, characterized in that the acoustic signal
is amplified.
4. A method as claimed in Claim 1, 2 or 3, characterized in that the acoustic signal
is converted into an electric, electronic and/or optical signal.
5. A device for performing the method claimed in one of the Claims 1 to 4, comprising
at least one displaceable vacuum pick-up means (105) which is connected to a vacuum
source (109) and a valve (111) which is operable to establish and interrupt communication
between the vacuum pick-up means (105) and the vacuum source (109), characterized
in that a sound generator (115) is interposed in the connection between the vacuum
pick-up means (105) and the vacuum source (109).
6. A device as claimed in Claim 5, characterized in that the sound generator (115)
is constructed as a vortex chamber (119).
7. A device as claimed in claim 6, characterized in that a microphone (125) is arranged
in the vortex chamber (11).
8. A device as claimed in Claim 7, characterized in that the microphone (125) is connected
to an electronic signal-processing unit (127).
9. A device as claimed in one of the claims 5 to 8 comprising a plurality of vacuum
pick-up means (105), characterized in that the plurality of vacuum pick-up means (105)
can be placed in communication with a common vacuum source (109) via a single common
valve (111).
1. Procédé pour détecter la présence ou l'absence d'un objet sur une buse d'aspiration
(105) qu'on peut faire communiquer avec une source de vide (109) et est conçue pour
saisir, transporter et mettre en place un objet, cet objet étant saisi et retenu par
la buse sous l'action du vide et étant lâché lors de l'interruption ou de la suppression
du vide, alors que la différence entre, d'une part, la pression régnant dans la buse
si celle-ci communique avec la source de vide et un objet est présent sur la buse
et, d'autre part, la pression régnant dans la buse si celle-ci communique avec la
source de vide et aucun objet n'est présent sur la buse, est utilisée pour engendrer
un signal de contrôle ou de défaillance, caractérisé en ce que pour la génération
du signal de contrôle ou de défaillance, est utilisé le courant d'air qui est produit
par le vide si la buse communique avec la source de vide et aucun objet n'est présent
sur la buse, courant d'air qui est converti en un signal acoustique indiquant l'absence
d'un objet sur la buse d'aspiration.
2. Procédé selon la revendication 1, caractérisé en ce que le signal acoustique est
engendré par création d'une turbulence dans le courant d'air.
3. Procédé selon la revendication 1 ou 2, caractérisé en ce que le signal acoustique
est amplifié.
4. Procédé selon la revendication 1, 2 ou 3, caractérisé en ce que le signal acoustique
est converti en un signal électrique, électronique et/ ou optique.
5. Dispositif pour la mise en oeuvre du procédé selon l'une des revendications 1 à
4, comportant au moins une buse d'aspiration mobile (105) raccordée à une source de
vide (109) et une vanne (111) permettant d'établir et d'interrompre la communication
entre la buse (105) et la source de vide (109), caractérisé en ce qu'un générateur
sonore (115) est interposé dans la communication entre la buse d'aspiration (105)
et la source de vide (109).
6. Dispositif selon la revendication 5, caractérisé en ce que le générateur sonore
(115) est réalisé sous la forme d'une chambre de tourbillonnement (119).
7. Dispositif selon la revendication 6, caractérisé en ce que dans la chambre de tourbillonnement
(11) est disposé un microphone (125).
8. Dispositif selon la revendication (7), caractérisé en ce que le microphone (125)
est relié à une unité électronique de traitement de signaux (127).
9. Dispositif selon l'une des revendications 5 à 8, comportant une pluralité de buses
d'aspiration (105), caractérisé en ce qu'on peut faire communiquer la pluralité de
buses (105) avec une source de vide commune (109) par l'intermédiaire d'une seule
vanne commune (111).
1. Verfahren zum Detektieren der An- oder Abwesenheit eines Gegenstandes an einer
Düsenöffnung (105), wobei die Düse mit einer Vakuumquelle (109) in Verbindung gebracht
und zum Aufnehmen, Transportieren und Absetzen eines Gegenstandes betrieben werden
kann, der unter dem Einfluss des Vakuums von der Düse aufgenommen und festgehalten,
und bei Unterbrechung oder Aufhebung des Vakuums freigegeben wird, und wobei der in
der Düse entstehende Druckunterschied, wenn einerseits die Düse mit der Vakuumquelle
in Verbindung steht und ein Gegenstand an der Düsenöffnung vorhanden ist, und wenn
andererseits die Düse mit der Vakuumquelle in Verbindung steht und kein Gegenstand
an der Düsenöffnung vorhanden ist, zum Erzeugen eines Prüf- oder Fehlersignals verwendet
wird, dadurch gekennzeichnet, dass der Luftstrom, der vom Vakuum erzeugt wird wenn
die Düse mit der Vakuumquelle in Verbindung steht und kein Gegenstand an der Düsenöffnung
vorhanden ist, zum Erzeugen des Prüf- oder Fehlersignals verwendet wird, wobei der
Luftstrom in ein akustisches Signal umgewandelt wird, das die Abwesenheit eines Gegenstandes
an der Düsenöffnung anzeigt.
2. Verfahren nach Anspruch 1, dadurch gekennzeichnet, dass das akustische Signal durch
im Luftstrom hervorgerufene Turbulenz erzeugt wird.
3. Verfahren nach Anspruch 1 oder 2, dadurch gekennzeichnet, dass das akustische Signal
verstärkt wird.
4. Verfahren nach Anspruch 1, 2 oder 3, dadurch gekennzeichnet, dass das akustische
Signal in ein elektrisches, elektronisches und/oder optisches Signal umgewandelt wird.
5. Vorrichtung zur Durchführung des Verfahrens nach einem oder mehreren der Ansprüche
1 bis 4, mit zumindest einer verschiebbaren Vakuumdüse (105), die an eine Vakuumquelle
(109) angeschlossen ist, und mit einem Ventil (111) zum Herstellen und Unterbrechen
der Verbindung zwischen der Vakuumdüse (105) und der Vakuumquelle (109), dadurch gekennzeichnet,
dass ein Schallgenerator (115) in der Verbindung zwischen der Vakuumdüse (105) und
der Vakuumquelle (109) angeordnet ist.
6. Vorrichtung nach Anspruch 5, dadurch gekennzeichnet, dass der Schallgenerator (115)
als Wirbelkammer (119) ausgebildet ist.
7. Vorrichtung nach Anspruch 6, dadurch gekennzeichnet, dass ein Mikrophon (125) in
der Wirbelkammer (11) angeordnet ist.
8. Vorrichtung nach Anspruch 7, dadurch gekennzeichnet, dass das Mikrophon (125) an
eine elektronische Signalverarbeitungseinheit (127) angeschlossen ist.
9. Vorrichtung nach einem oder mehreren der Ansprüche 5 bis 8, mit einer Vielzahl
von Vakuumdüsen (105), dadurch gekennzeichnet, dass die Vielzahl von Vakuumdüsen (105)
über ein einziges gemeinsames Ventil (111) mit einer gemeinsamen Vakuumquelle (109)
in Verbindung gebracht werden kann.